Method and apparatus for updating a key in an active state

ABSTRACT

A method for updating a key in an active state is disclosed according to the embodiments of the present invention. The method includes steps of: initiating a key update by a user equipment in the active state or a network side when a pre-defined condition is met; updating the key by the network side and the user equipment, and negotiating an activation time of the new keys. An apparatus for updating a key in an active state is also disclosed according to the present invention. With the present invention, the user equipment in an active state and the network side may actively initiate the key update procedure in different cases, thereby solving the problem concerning the key update for a session in an active state.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 12/748,798, filed on Mar. 29, 2010 (now U.S. Pat. No. 8,300,827, which issued Oct. 20, 2012), which is a continuation of International Patent Application No. PCT/CN2008/072534, filed on Sep. 25, 2008, which claims priority to Chinese Patent Application No. 200710151885.5, filed on Sep. 28, 2007, all of which are hereby incorporated by reference in their entireties.

FIELD OF THE INVENTION

The present invention relates to communications field, and more specifically, to method and apparatus for updating a key in an active state.

BACKGROUND

To guarantee the competitive edge of the 3GPP (3rd Generation Partnership Project) in the future, the work on evolved access technology is in progress within the 3GPP organization. Especially to strengthen the capability of 3GPP system for processing rapidly increasing IP data service, packet technology employed in the 3GPP system requires further improvement. Some most important parts of such evolved technology include: decreased delay and reaction time, accelerated user data rate, enhanced system capacity and coverage, and reduced overall cost of the operators. Moreover, the evolved network structure is also an important indicator for the backward compatibility of the existing network. In terms of the security therein, the user security procedure in the evolved network is required to guarantee that a security mechanism is provided which at least has a same level as that of the current 2G and 3G system.

As shown in FIG. 1, the core network of the wireless evolved network mainly includes logic function entities such as a Mobility Management Entity (MME), a System Architecture Evolution Gateway (SAE Gateway), and so forth. The MME is responsible for mobility management of control plane including managing the user context and mobility state, allocating temporary user identification, security function, etc. The SAE Gateway is responsible for paging downlink data in an idle state, managing and storing IP bearer context and routing information in the network, etc., serving as an anchor point for user plane between different access systems. In the wireless evolved network, the security of the user plane is terminated at the access network, where a Base Station (BS) of the access network is referred to as an evolved NodeB (eNB). The security of the signaling plane is divided into two parts, namely Access Stratum signaling Radio Resource Control (RRC) and Non Access Stratum (NAS) signaling, terminated at the access network and the core network respectively. The key required to secure the signaling and the data is derived diversely from keys, i.e., CK, IK, generated during an Authentication and Key Agreement (AKA) procedure. The deriving relations are illustrated as FIG. 2.

Therein, K_(eNB-RRC-INI) is a security key for the integrity of RRC signaling, K_(eNB-RRC-ENC) is a security key for the encryption of RRC signaling, and K_(eNB-RRC-UP) is a security key for the encryption of user plane data, whereas K_(NAS-ENC) is a security key for the encryption of the NAS, and K_(NAS-INI) is a security key for the integrity of NAS signaling.

SUMMARY

A method and an apparatus for updating a key in an active state are provided according to embodiments of the present invention, in order to update the key in the active state.

To this end, a method for updating a key in an active state is provided according to an embodiment of the present invention. The method includes following steps:

initiating a key update by a user equipment in the active state or a network side when a pre-defined condition is met; and

updating the key by the network side and the user equipment, and negotiating an activation time of the new keys.

A user equipment for updating a key in an active state is also provided according to an embodiment of the present invention. The user equipment includes:

a terminal key update detecting unit, configured to determine based on a pre-defined condition whether a key update needs to be initiated; and

a terminal key update initiating unit, configured to send a key update request message to a network side when the terminal key update detecting unit determines that the key needs to be updated.

A network side entity for updating a key in an active state is also provided according to an embodiment of the present invention. The network side entity includes:

a key update detecting unit, configured to determine based on a pre-defined condition whether a key update needs to be initiated;

a key update initiating unit, configured to send a request message for indicating the key update, when the key update detecting unit determines that the key needs to be updated; and

a key updating unit, configured to update the key when the user equipment or the network side entity initiates the key update.

Another method for updating a key in an active state is also provided according to an embodiment of the present invention.

initiating, by a network side, a key update when a pre-defined condition is met; and

updating the key by the network side, and informing a user equipment of the new key.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a schematic of a wireless evolved network according to the conventional art;

FIG. 2 illustrates a schematic of deriving relations regarding keys according to the conventional art;

FIG. 3 illustrates a flowchart of a method for updating a key in an active state according to a first embodiment of the present invention;

FIG. 4 illustrates a flowchart of updating a key in an active state which is actively initiated by a UE according to a second embodiment of the present invention;

FIG. 5 illustrates a flowchart of updating a key in an active state which is actively initiated by an eNB at a network side according to a third embodiment of the present invention;

FIG. 6 illustrates a flowchart of updating a key in an active state which is actively initiated by an eNB at a network side according to a fifth embodiment of the present invention;

FIG. 7 illustrates a flowchart of updating a key in an active state which is actively initiated by an MME at a network side according to a sixth embodiment of the present invention;

FIG. 8 illustrates a flowchart in which an eNB informs a UE of new keys via an air-interface key update procedure according to a seventh embodiment of the present invention;

FIG. 9 illustrates a flowchart in which an eNB informs a UE of new keys via an air-interface key update procedure according to an eighth embodiment of the present invention; and

FIG. 10 illustrates a schematic of a system for updating a key in an active state according to a ninth embodiment of the present invention.

DETAILED DESCRIPTION

In implementing the present invention, it is discovered that the above conventional schema encounters at least the following problems.

In the System Architecture Evolution (SAE)/Long Term Evolution (LTE) system, related discussion involving methods of how the key can be instantly applied to an activating conversation after the key negotiation has already been proposed. All of the methods therein are proposed given that the key has already been updated to be a new key, but no procedure regarding how to acquire the new key is involved. Therefore, it is necessary to provide a method for addressing the issue of how to negotiate new keys in an active state. In addition, the key update in the active state requires that the network side may also have the capacity for initiating the key negotiation. In the conventional art, the network side will not actively initiate the key update procedure. Rather, only after the user switches from a non-active state into an active state and initiates an initial NAS message to the network side, e.g., an attach request, a paging response, a location update request, etc., the network side may determine whether a certain kind of key needs to be updated.

Detailed description will be made to the present invention in connection with the annexed drawings and embodiments.

In the first embodiment of the present invention, a method for updating a key in an active state is that a user equipment (UE) may determine whether the key needs to be updated in the active state. The method for updating the key in the active state is as shown in FIG. 3. The method includes below steps.

Step s301: A user equipment in an active state or a network side may determine that a key update is required based on a pre-configuration, and initiate the key update.

The pre-configuration may include: (1) the user equipment finds out that a COUNT to which the User Plane (UP) or the RRC related is arriving at an upper threshold; (2) the user equipment has performed a handover between two eNBs, a handover within one eNB, or an inter-system handover; (3) the user equipment or the network side finds out that K_(ASME) has not been updated for a long period.

Step s302: The network side performs the key update procedure.

The key update includes: updating all of the keys through the AKA authentication procedure; or, only updating derived keys of K_(ASME) rather than performing AKA to update K_(ASME).

Step s303: The user equipment and the network side may acquire the updated keys.

Step s304: After the new keys are acquired, the user equipment and the network side may negotiate an activation time of the new keys.

Detailed description will be made to the present invention in connection with different application scenarios.

In the second embodiment of the present invention, a method for updating a key in an active state is as shown in FIG. 4, where the UE may actively initiate the key update procedure in the active state. The method includes below steps.

Step s401: When in active state, the UE finds out that the key needs to be updated due to some reason, the UE may actively trigger the key update procedure to the MME at the network side.

The possible reasons for updating the key may include: (1) the COUNTs to which the UP or the RRC related is arriving at the upper threshold; (2) the UE just has performed a handover to a new eNB; (3) K_(ASME) has not been updated for a long period. The UE may trigger the key update procedure by sending to the MME, a TAU/RAU request, or a special attach request, or a special service request, or a key update request message.

If the key update is trigged by means of sending a TAU/RAU message as the key update request, even if no update occurs for location/routing area of the UE, this TAU/RAU request may also be sent, in which that the old routing area identification is identical with the new routing area identification. To identify the key update request, Update type in the TAU/RAU request may be set as a special value, indicating that the key needs to be updated. The special value may utilize a unified special value for different reasons, or may distinctively utilize different values regarding different reasons (a RRC/UP counter value overflows, or a handover has been performed, or lifetime of K_(ASME) expires). Or, the UE may not indicate, but employ several existing values (e.g., the values indicating the routing/location area changing). In addition, since a periodic location registration requires no key update, the Update type shall be distinguished from it. To distinguish from the periodic location/routing registration, it is better for the Update type to employ a value other than the value indicating the “Periodic updating” such as 000.

Notes: several values for the Update type in the existing UMTS are as shown in Table 1.

TABLE 1 0 0 0 RA updating 0 0 1 combined RA/LA updating 0 1 0 combined RA/LA updating with IMSI attach 0 1 1 Periodic updating

Step s402: After the MME receives the request that triggers the key update procedure (may be one of the requests mentioned at step 401), the MME may perform the related key update procedure according to the request type.

The AKA authentication procedure may be initiated if K_(ASME) needs to be updated, e.g., an inter-system handover has been performed from GSM/UMTS to SAE/LTE, or lifetime of K_(ASME) expires.

New derived keys may be calculated based on K_(ASME), if there is no need to update K_(ASME), and only its derived keys need to be updated, e.g., the key update is required when a handover has been performed within the LTE system, or as a RRC/UP counter value arrives at an upper threshold, in which case only K_(eNB), or together with K_(NAS-int) and K_(NAS-enc) may be updated.

Step s403: The AKA procedure is performed to update the keys if it is determined to update K_(ASME) at step s402. This step is optional.

Step s404: Each key is updated according to the determination at step s402. The related key is calculated based on the existing K_(ASME) key, if only the derived keys of K_(ASME) needs to be updated.

Step s405: The MME sends the new keys to the eNB.

Step s406: The eNB and the UE negotiate the activation time of the new keys.

The eNB may notify the activation time of the new keys using one of the following methods, or a method other than the following ones.

(1) The eNB may inform the UE of the activation time of the new keys via a simplified security mode command, and the UE may acknowledge the reception of the security mode command. The UE and the network side may activate the new key according to the activation time of the new keys. If the NAS keys need to be updated, step s405 may further include initiating an NAS security mode command in order to negotiate the activation time of new NAS keys.

(2) The eNB may initiate an intra-cell handover command, requesting the UE to perform handover to a current serving cell of the eNB itself so that the UE may use the new keys.

(3) The eNB may add a KSI along with each data packet in order to indicate which key the UE could use for decryption.

In addition to the above methods, one may also refer to the below description described in step s801 in the seventh embodiment or step s901 in the eighth embodiment.

Step s407: The network side sends a response message to the user in order to complete all the procedures for key update.

It is to be noted that the activation time of the new NAS keys may also be carried in this response.

In the third embodiment of the present invention, a method for updating a key in an active state is as shown in FIG. 5, where the eNB at the network side may actively initiate the key update procedure in the active state.

The present embodiment refers to the key update procedure initiated by the eNB. When the COUNTs related to the UP or RRC encryption/integrity security is about to arrive at an upper threshold (about to wrap around), the related key may probably need to be updated in order to prevent repeated key stream. Or, even if the COUNTs does not arrive at the upper threshold, but the UE is in LTE_ACTIVE state for a long period, the user plane security key, i.e., Kup-enc or KeNB, may probably need to be updated. In the two scenarios above, there is no need to update K_(ASME) and K_(MME), only K_(up) and K_(RRC) need to be updated. Of course, at this point, K_(ASME) may also be updated.

The key update procedure in the third embodiment is described as follows.

Step s501: When the eNB finds out the key needs to be updated according to the above security requirement, the eNB may send to the MME a key update request message, requesting the MME to generate a new K_(eNB). The MME may then derive a new K_(eNB) from K_(ASME).

The key update request message may probably be: (1) a request message specifically for requesting the MME to update the key by the eNB, where an MME response is required regarding this request message; (2) a notification type of message, notifying the MME that the key needs to be updated, where no MME response is required regarding this notification message.

Step s502: The MME may update the key, K_(eNB), accordingly. Therein, K_(eNB) may be derived by the MME from the existing K_(ASME), or, may be calculated by the MME after K_(ASME) is updated through the AKA procedure.

Step s503: The MME sends the new K_(eNB) to the eNB. The MME may send the key to the eNB in the following manners:

(1) via a key update response message corresponding to the key update request sent by the eNB according to step s501;

(2) via a context modification message actively initiated by the MME, where the new key is sent to the eNB in the modification message;

(3) via a security context modification message actively initiated by the MME, where the new key is sent to the eNB in the modification message.

It is to be noted that in addition to the new K_(eNB), the MME may also need to send other parameters required for calculating K_(eNB) to the eNB in the above manners. For example, when the MME is calculating the new key using the existing K_(ASME), a variable parameter (e.g., a counter, a random number) may probably need to be introduced. Thus, this variable parameter may also need to be sent to the eNB and then sent to the UE via the eNB, so that the UE may calculate the new K_(eNB) using the same parameter.

The eNB may derive new Kp and K_(RRC) based on this new K_(eNB). C-RNTI or a random number may be employed as an input parameter during the deriving procedure. If C-RNTI is employed, the original C-RNTI may probably be utilized, or a C-RNTI parameter may probably be newly generated for the UE.

Step s504: An air-interface new key initiating procedure, i.e., a method concerning how to negotiate an activation time of the new keys is provided. In addition to the methods descried in the prior description such as the Packet Data Convergence Protocol (PDCP) SN or KSI, or the UE is forced to perform an active-idle-active state transition, or an intra-cell handover, one may also refer to the below description described in step s801 and step s802 in the seventh embodiment or step s901 and step s902 in the eighth embodiment.

If the MME sends K_(eNB) in the manner (2) at step s503, the eNB may probably need to send a response message of (security) context modification after the new key is activated.

In the fourth embodiment of the present invention, a method for updating a key in an active state is as shown in FIG. 5, where the eNB at the network side may actively initiate the key update procedure in the active state.

The present embodiment refers to the key update procedure initiated by the eNB. When the COUNTs related the UP or RRC encryption/integrity security is about to arrive at an upper threshold (about to wrap around), the related key may probably need to be updated in order to prevent repeated key streams. Or, even if the COUNTs does not arrive at the upper threshold, but the UE is in LTE_ACTIVE state for a long period, the user plane security key, i.e., K_(UP-enc) or K_(eNB), may probably need to be updated. In the two scenarios above, there is no need to update K_(ASME) and K_(MME), only K_(up) and K_(RRC) need to be updated.

The difference between the third embodiment and the present embodiment is that K_(eNB) is updated in the third embodiment whereas K_(eNB) is not updated in the present embodiment. The key update procedure in the fourth embodiment is described as follows.

(1) When the eNB finds out that the key needs to be updated (the eNB finds out that the key needs to be updated according to the security requirement mentioned above), the eNB may generate a random number or a new C-RNTI, and then generate a new RRC/UP key using K_(eNB) and other parameters.

(2) The eNB may inform the UE of the new key parameters via the air-interface key update procedure. The air-interface key update procedure utilized herein may refer to the description of following embodiments.

In the fifth embodiment of the present invention, a method for updating a key in an active state is as shown in FIG. 6, where the eNB at the network side may actively initiate the key update procedure in the active state. The method includes below steps.

Step s601: In a non-handover scenario, if the network side such as eNB desires to update the key, an intra-cell handover command is thus sent to the UE, i.e., requesting the UE to perform handover to the source cell (target cell is identical with source cell).

Step s602: The UE may access the eNB cell again upon the receipt of the handover command.

The description of step s603 to step s609 in the follow-up procedure may refer to step s401 to step s407 in the second embodiment, which is omitted herein for brevity.

In the sixth embodiment of the present invention, a method for updating a key in an active state is as shown in FIG. 7, where the MME at the network side may actively initiate the key update procedure. The method includes below steps.

Step s701: When the MME at the network side finds out that K_(ASME) has been used for a long period or an inter-RAT handover has been performed to the UE and so forth, after which K_(ASME) needs to be updated, the MME may then determine to actively initiate the AKA procedure. The network side needs to set a valid time for each K_(ASME) so that a corresponding procedure can be triggered instantly when the valid time arrives at the upper threshold.

Step s702: The MME actively initiates a special paging message to the UE. This step is optional.

A Paging cause of the special paging request may be NULL or a special value indicative of the key update.

Step s703: The UE sends a paging response to the network upon the receipt of the paging message.

Steps s702 and s703 are optional.

Step s704: When the MME sends to the UE an authentication request message in order to initiate to perform the AKA, or upon the receipt of the paging response, similar to the receipt of the paging message according to the conventional art, the MME may thus determine to perform the AKA, and may initiate the AKA procedure to the UE.

Step s705: The MME generates each derived key.

Step s706: The MME sends K_(eNB) to the eNB. K_(eNB) may be sent specifically in the manner of carrying the K_(eNB) in the NAS message and informing the UE of the activation time of the new NAS keys, which is optional.

The MME may send the new key to the eNB in one of the following manners:

(1) employing a context modification message that is actively sent to the eNB; the context modification message may employ a special 51 initial context establishment message, or a newly defined 51 interface signaling. The context modification message includes the new key.

(2) employing a security context modification message that is actively sent to the eNB. The security context modification message includes the new key.

Of course, other similar messages may also be employed for the sending.

Step s707: The eNB and the UE negotiate the activation time of the new keys. Optionally, the activation time of the NAS keys may also be negotiated during this procedure.

Step s708: The user communicates with the network side using the new keys.

In respect of the newly generated key, the eNB needs to inform the UE of the start of the new keys via the air-interface key update procedure. During the key update procedure, the main purpose of the air-interface key update procedure is to: (1) send parameters relating to the derived keys to the UE, e.g., a new C-RNTI or a random number; (2) inform the UE of the activation time of the keys.

In the seventh embodiment of the present invention, the description is made by way of Security Mode Command (SMC) procedure as an example, where the eNB informs the UE of the start of the new keys via the air-interface key update procedure. Referring to FIG. 8, following steps are included.

Step s801: The eNB determines based on triggering reasons that a special SMC message needs to be sent to the UE.

The SMC message may include one or more of the following parameters: (1) parameters required for deriving the key such as a new C-RNTI, a random number, and so forth; (2) a downlink activation time of the NAS keys; (3) a downlink activation time of the RRC keys; (4) an uplink and a downlink activation time of the user plane keys; (5) other possible parameters, e.g., an activation time of new keys for determining uplink data packets (including data packets of the user plane and the control plane).

In addition, when a downlink message is sent by the eNB, the eNB may: (1) stop sending the downlink data, so that the downlink activation time may begin from a next data packet; (2) continue to send data packets, but the PDCP SN for activating using of new keys may be set a little larger so as to avoid a key activation error due to the rapid sending of the packets.

Of course, in addition to the SMC message, a new command such as newly defined security context modification command/security re-configuration command may also be utilized to request the UE to switch the key in use according to parameters or a time carried in the command.

Step s802: The UE returns a corresponding message to the eNB upon the receipt of the related message.

Specifically, upon the receipt of the SMC message, the UE may derive new keys based on the related parameters. Optionally, an activation time of the uplink data packets (including data packets of the user plane and the control plane) may also be required. The UE may then return the related message to the eNB. A PDCP SN for initiating the new keys is carried in the related message. The UE may not stop sending the data packets, but calculate new keys and acquire activation time of the new keys, and then send the new activation time to the eNB. At this point, the activation time of the keys for the uplink data packets needs to be set a little backward if this method is adopted.

Step s803: The air-interfaces may communicate under the protection of the new keys.

In the eighth embodiment of the present invention, the description is made by way of an intra-cell handover procedure as an example, where the eNB informs the UE of a new key activation via the air-interface key update procedure. Referring to FIG. 9, following steps are included.

Step s901: The eNB determines based on triggering reasons that an HO Command message needs to be sent to the UE.

In normal cases, the HO Command message may be sent to the UE in order to tell the UE to perform handover to another Cell, so that the HO Command message may carry air recourses, C-RNTI, etc., assigned by the another Cell. However, in the embodiment, the HO Command message is merely to tell the UE to activate the updated keys rather than to instruct the UE to perform handover to other Cells. Therefore, some transformations on the parameters may be required: (1) “transparent container for Target eNB to UE” in the original HO Command message should be removed; (2) the C-RNTI in the original message assigned to the UE by “target eNB cell” shall be modified as a new C-RNTI assigned by “Source eNB cell” itself; (3) an activation time of the NAS keys probably required should be added; (4) a downlink activation time of the RRC keys shall be added; (5) a downlink activation time of the user plane keys shall be added; (6) values for the reason shall be added, telling the UE that the present HO Command message is to instruct the UE to update the key rather than to perform a real handover.

Moreover, according to general requirements of the HO Command, the eNB will not deliver any data packet after the HO Command message is sent.

Step s902: After the HO Command message is received by the UE, the UE may: (1) determine based on the values of the reason that the present handover is merely for the key update, and therefore synchronizing with the new cell is not required; (2) stop sending the uplink data packets; (3) derive new keys; (4) determine an activation time of the uplink data packets; (5) send a message to the eNB, informing the eNB of the activation time of the uplink data packets.

Step s903: The UE and the eNB may communicate with each other under the protection of the new keys.

With the methods provided according to the embodiments of the present invention, the user equipment in the active state and the network side may actively initiate the key update procedure in different cases, thereby solving the problem concerning the key update for a session in the active state. In addition, the implementation procedure is simple and easy to accomplish.

In the ninth embodiment of the present invention, a system for updating a key in an active state is also disclosed. Referring to FIG. 10, the system includes at least a user equipment 10 and a network side entity 20, where the user equipment in the active state and the network side entity may initiate the key update and update the key when a pre-defined condition is met.

Specifically, the user equipment 10 further includes:

a terminal key update detecting unit 11, configured to determine based on a pre-defined condition whether the key update needs to be initiated;

a terminal key update initiating unit 12, configured to send a key update request message to the network side entity 20 when the terminal key update detecting unit 11 determines that the key needs to be updated; and

a terminal key update setting unit 13, configured to pre-define the condition for initiating the key update and provide the condition to the terminal key update detecting unit 11.

Specifically, the network side entity 20 specifically includes:

a key update detecting unit 21, configured to determine based on a pre-defined condition whether the key update needs to be initiated;

a key update initiating unit 22, configured to send a request message to the user equipment 10 for instructing the key update, when the key update detecting unit 21 determines that the key needs to be updated;

a key updating unit 23, configured to update the key when the user equipment 10 or the network side entity 20 initiates the key update;

a key update setting unit 24, configured to pre-define the condition for initiating the key update and provide the condition to the key update detecting unit 21; and

a key start negotiating unit 25, configured to negotiate an activation time of the new keys with the user equipment.

Therein, the functions of the units mentioned above may be realized via the MME at the network side and the eNB.

With the systems and the apparatuses provided according to the embodiments of the present invention, the user equipment in the active state and the network side may actively initiate the key update procedure in different cases, thereby solving the problem concerning the key update for a session in the active state. In addition, the implementation procedure is simple and easy to accomplish.

Compared with the conventional art, the embodiments of the present invention enjoy the following advantages: The user equipment in the active state and the network side may actively initiate the key update procedure in different cases, thereby solving the problem concerning the key update for a session in the active state.

With the description of the foregoing embodiments, it is readily appreciated by those skilled in the art that the present invention may be implemented with hardware, and may also be implemented with software on a necessary hardware platform. Based on this understanding, solutions provided by the present invention may be embodied in a software product. The software product may be stored in a nonvolatile storage media (may be a CD-ROM, a USB flash disc, a mobile hard disc, etc.) The software product may include a set of instructions enabling a computer device (may be a personal computer, a server, or a network device, etc.) to perform methods according to various embodiments of the present invention. In addition, the foregoing embodiments take SAE/LTE system as an example. The eNB described in the foregoing embodiments refers to a Base Station (BS) of the SAE/LTE system. It is readily appreciated by those skilled in the art that the BS is not limited to the eNB. Any Base Station that realizes the similar function as the eNB stated above shall fall within the scope of protection of the present invention.

In summary, the foregoing is merely preferred embodiments of the present invention and is not intended to be limiting to the scope of the present invention. Any modifications, equivalents, improvements made within the spirit and principle of the present invention shall be construed as fall within the scope of the present invention. 

What is claimed is:
 1. A user equipment for updating a key in an active state, comprising: a receiver, configured to receive, from an evolved NodeB (eNB), an intra-cell handover command which is configured to instruct the user equipment to use air-interface keys; wherein the air-interface keys are updated based on a new key K_(eNB); wherein the new key K_(eNB) is derived based on a key which is generated during a key update procedure; wherein the key update procedure is initiated by a Mobility Management Entity (MME) when a pre-defined condition is met; a transmitter, configured to send an acknowledgement for receiving the intra-cell handover command; and a processor, configured to apply the air interface keys in a security operation to a subsequent message received or sent by the user equipment.
 2. The user equipment according to claim 1, wherein the pre-defined condition comprises that the user equipment has performed one of: a handover between two eNBs, a handover within one eNB, and an inter-system handover.
 3. The user equipment according to claim 1, wherein the security operation is any one of integrity protection, encryption and decryption.
 4. A method for updating a key in an active state, the method being performed in a user equipment (UE), comprising: receiving, from an evolved NodeB (eNB), an intra-cell handover command which is configured to instruct the UE to use air-interface keys; wherein the air-interface keys are updated based on a new key K_(eNB); wherein the new key K_(eNB) is derived based on a key which is generated during a key update procedure; wherein the key update procedure is initiated by a Mobility Management Entity (MME) when a pre-defined condition is met; sending an acknowledgement for receiving the intra-cell handover command; and applying the air interface keys in a security operation to a subsequent message received or sent by the UE.
 5. The method according to claim 4, wherein the pre-defined condition comprises that the user equipment has performed one of: a handover between two eNBs, a handover within one eNB, and an inter-system handover.
 6. The method according to claim 4, wherein the security operation is any one of integrity protection, encryption and decryption. 